Photographic lighting system and method

ABSTRACT

Photographic lighting devices, systems, and methods having a plurality of electrical energy storage/discharge (EESD) elements and/or one or more light sources in a single photographic lighting device to perform one or more photographic lighting effects. EESD elements and one or more light sources can be configured to have multiple separate light emissions occur in a single image acquisition window. The multiple light emissions are separated in an image acquisition window by a time period that is about shutter speed exposure time/(N−1), where N is the number of light emissions. In one such example, two light emissions are separated by a time period that is about shutter speed exposure time/(N−1).

RELATED APPLICATION DATA

This application is a continuation of U.S. patent application Ser. No.16/221,934, titled “Photographic Lighting System and Method,” filed Dec.17, 2018, which is a continuation application of U.S. patent applicationSer. No. 15/633,216, titled “Photographic Lighting System and Method,”filed Jun. 26, 2017, which is a continuation application of U.S. patentapplication Ser. No. 14/533,067, titled “Photographic Lighting Systemand Method,” filed on Nov. 4, 2014, each of which is incorporated byreference herein in its entirety.

This application also claims the benefit of priority of U.S. ProvisionalPatent Application Ser. No. 61/899,870, filed Nov. 4, 2013, and titled“Photographic Lighting System and Method,” which is incorporated byreference herein in its entirety.

FIELD OF THE INVENTION

The present invention generally relates to the field of photographiclighting. In particular, the present invention is directed to aphotographic strobe system and method.

BACKGROUND

Proper lighting is an essential element for creating desirablephotographs. While many photographs are made using only natural or otherambient lighting, many more are made using dedicated photographiclighting provided solely for the purpose of capturing photographicimages having the “right” exposure desired by the photographer. Commonphotographic lighting devices are strobes and other flashes.

BRIEF DESCRIPTION OF THE DRAWINGS

For the purpose of illustrating the invention, the drawings show aspectsof one or more embodiments of the invention. However, it should beunderstood that the present invention is not limited to the precisearrangements and instrumentalities shown in the drawings, wherein:

FIG. 1 is a one example of an image acquisition in a camera that has twomoving shutters;

FIG. 2 is a high-level block/schematic diagram of an example of aphotographic strobe system;

FIG. 3 is graph of exemplary flash intensity-versus-time curves for aTTL pre-flash, a full-power, first-curtain image-capture flash and areduced-power, first curtain image-capture flash;

FIG. 4 is a graph of exemplary flash intensity-versus-time curves for afull-power, second-curtain image-capture flash and a reduced-power,second curtain image-capture flash;

FIG. 5 is a graph of an exemplary flash intensity-versus-time curve fora constant-level image-capture flash;

FIG. 6 is a graph of exemplary flash intensity-versus-time curves formultiple flashes strobed within a single exposure period;

FIG. 7 is a graph of exemplary flash intensity-versus-time curves formultiple rapidly fired flashes for rapidly capturing sequential images;

FIG. 8 is a graph of exemplary flash intensity-versus-time curvesillustrating enhanced intensity image capture flashes that can beachieved with a photographic strobe system of the present disclosure;

FIG. 9 is a graph of exemplary flash intensity-versus-time curves for acombined first- and second-curtain sync image-capture flash that can beachieved with a photographic strobe system of the present disclosure;

FIG. 10 is a graph of exemplary flash intensity-versus time curves for acombined first-curtain sync plus constant-level image capture flash thatcan be achieved with a photographic strobe system of the presentdisclosure;

FIG. 11 is a graph of exemplary flash intensity-versus time curves for acombined second-curtain sync plus constant-level image capture flashthat can be achieved with a photographic strobe system of the presentdisclosure;

FIG. 12 is a graph of exemplary flash intensity-versus-time curves formultiple flashes strobed within a single exposure period that can beachieved with a photographic strobe system of the present disclosure;

FIG. 13 is a graph of exemplary flash intensity-versus-time curves formultiple rapidly fired flashes for rapidly capturing sequential imagesthat can be achieved with a photographic strobe system of the presentdisclosure;

FIG. 14 is a schematic diagram of an exemplary strobe light having twolight sources;

FIG. 15 is an isometric view of an exemplary photographic strobe device;

FIG. 16 is a rear elevational view of the photographic strobe device ofFIG. 15;

FIG. 17 is a diagrammatic view of an exemplary photographic system; and

FIG. 18 is a diagrammatic view of another exemplary photographic system.

DETAILED DESCRIPTION

The present disclosure includes description of implementations of aphotographic lighting device system and method involving multipleelectrical energy storage/discharge (EESD) elements and/or multiplelight sources in a single photographic lighting device to perform one ormore photographic lighting effects.

A photographic lighting device is a device that provides light that canbe used during photographic image acquisition. Examples of aphotographic lighting device include, but are not limited to, a flashdevice, a constant light source, a near constant light source, and anycombinations thereof. Examples of a flash device include, but are notlimited to, a strobe device (e.g., a studio strobe light), aphotographic speedlight, and any combinations thereof. Several examplesbelow that are described with respect to FIGS. 2 to 18 utilize the term“strobe” and “strobe device” for convenience. It is contemplated andshould be understood that where these terms are used herein, anyphotographic lighting device could also be used in place of the“strobe.” For example, a photographic speedlight can replace the studiostrobe and have the features and structures described below.

A photographic image acquisition typically involves the use of a camerahaving a sensor for capturing an image. Example sensors include, but arenot limited to, an electronic sensor, a film sensor, and anycombinations thereof. Many modern cameras (e.g., a digital SLR camera)utilize electronic sensors. An image acquisition window is a timeframein which an image is acquired (e.g., using a photographic sensor). Thebeginning and end of an image acquisition window may be controlled invarious ways known in the photographic arts. In one example, a cameramay include one or more shutters for blocking and/or allowing light topass to a sensor. In another example, electronic gating of a sensor canbe utilized to start and stop an image acquisition window (e.g., gatingthe data acquisition from an electronic sensor in a shutter-lesscamera). FIG. 1 illustrates one example of an image acquisition in acamera that has two moving shutters (a first shutter and a secondshutter). In a starting position, the shutter mechanism is closed andblocks light to a sensor of the camera. The first shutter blade moves toopen and expose the sensor to the light of the image (e.g., lightpassing through an aperture of a lens). The second shutter blade movesto close and block light from passing to the sensor. At slower shutterspeeds (i.e., longer exposures), the first shutter may stop movement andbe fully open before the second shutter starts to move to block thesensor. At faster shutter speeds (i.e., shorter exposures), the secondshutter blade may start to block the sensor prior to the first shutterblade completing its movement across the sensor. In FIG. 1, a plot 105shows the position of a first shutter blade over time. The initial flatportion of the plot indicates a position that blocks light to a sensor.The later flat portion of the plot indicates a position in which thefirst shutter is no longer moving and no longer blocks light to thesensor. The sloped portion of the plot indicates the movement of thefirst shutter blade across the sensor from the position that blockslight to the position that allows light to pass. During the slopedportion the shutter blade partially blocks the sensor. Plot 110 showsthe position of a second shutter blade over time. The initial flatportion of the plot indicates a position of the second shutter bladethat allows light to pass to the sensor. The later flat portion of theplot indicates a position of the second shutter blade that in which theshutter blade blocks light to the sensor. The sloped portion of the plotindicates the movement of the second shutter blade across the sensorfrom the position that allows light to pass to the position that blockslight. During the sloped portion the second shutter blade partiallyblocks light to the sensor.

Time segment 115 (between dotted lines 120 and 125) indicates a segmentof time in which neither shutter blade is blocking light to the sensor.This time segment can be viewed as an image acquisition window. Inanother example, an image acquisition window starts at the beginning offirst shutter blade movement and ends at the end of second shutter blademovement. In yet another example, an image acquisition window startswhen the first shutter blade moves to a position that starts to allowlight to pass to a sensor (this position may be some time after theblade starts to move due to space on the side of a sensor over which ablade may move) and ends when a second shutter blade moves to a positionthat fully blocks light from passing to the sensor (this position may besome time before the blade stops movement). In still another example, animage acquisition window may be gated electronically with or withoutshutter movements. A shutter speed of an image acquisition is typicallythe time between the first shutter blade starting to move and the secondshutter blade starting to move (this can also be measured from the timewhen the first shutter blade stops movement to the second shutter bladestopping movement). As discussed above, at faster shutter speeds (e.g.,greater than 1/250^(th) of a second) the movement of the shutter bladesmay overlap providing for no fully open image acquisition window. Insuch an example, an open slit between the shutter blade edges allowslight to pass to different portions of the sensor as the slit movesacross the sensor.

FIG. 1 shows a plot of light emission intensity 130 for a photographiclighting device that is caused to emit light in association with theimage acquisition window for the camera. A flash pulse of light 135 isemitted in time segment 115 such that the light emission is available tothe sensor during the fully open image acquisition window. In oneexample, at faster shutter speeds an image acquisition window can bemeasured from the time when the first shutter blade moves to a positionthat starts to allow light to pass to a sensor and ends when a secondshutter blade moves to a position that fully blocks light from passingto the sensor.

It is noted that the plotting of a first and second shutter blademovement can be combined into a single plot that looks a bit like aparallelogram. This type of plot is used below with respect to FIGS. 3to 13 to show exposure periods associated with various light emissions.

In some examples of TTL (“through the lens”) flash photography, apreflash is utilized to provide light to a scene that is measuredthrough the lens of the camera. A preflash typically occurs prior toimage acquisition (e.g., prior to a first shutter blade beginningmovement). The measurement of the light is utilized to determine a powerlevel for a main flash that will be used during image acquisition. Priorart systems known to the inventor utilize a single flash light sourcefor both the preflash and the main flash. For example, a photographicspeedlight includes a single flash tube for emitting light for both thepreflash and the main flash.

A photographic lighting device may include two or more EESD elements forproviding flexibility to the type of light emission during an imageacquisition window, the number of light emissions during an imageacquisition window, and/or the position of one or more light emissionsduring an image acquisition window. Such a photographic lighting devicemay provide a variety of light emission functionalities. Examplefunctionalities that may be provided by a multiple EESD element singlephotographic lighting device include, but are not limited to, using afirst light source coupled to one or more EESD elements as a TTLpreflash and a second light source of the same lighting device for amain TTL flash; using multiple EESD elements fired together (e.g.,coupled to multiple light sources, coupled to a single light source) toemit light for a single image acquisition; using multiple EESD elementsfired in series (e.g., coupled to a single light source, coupled tomultiple light sources) to emit light for a single image acquisition;using multiple EESD elements fired in series (e.g., coupled to multiplelight sources, coupled to a single light source) to emit light for aseries of multiple image acquisitions; using a first EESD element topower a first light source for a flash-type light emission and a secondEESD element to power a second light source for constant/near constantlight emission during a single image acquisition (e.g., having theflash-type light emission occur at the beginning of the exposure withthe constant/near constant light emission at the later portion of theexposure (first curtain flash pop), having the flash-type light emissionoccur at the end of the exposure with the constant/near constant lightemission at the earlier portion of the exposure (rear-curtain flashpop)); and any combinations thereof.

In one example, a lighting device includes a single light source coupledto the two or more EESD elements. In another example, a lighting deviceincludes a plurality of light sources coupled to the two or more EESDelements. In one such example, each light source is coupled to acorresponding one of the two or more EESD elements. In another suchexample, two or more of the plurality of light sources are coupled toeach of the two or more EESD elements. In yet another such example, twoor more of the two or more EESD elements are coupled to each one of theplurality of light sources. In still another example, a combination ofany of the previous examples is employed in a photographic lightingdevice. While several of the example implementations below will bediscussed with respect to two or more EESD elements, it is contemplatedthat a single EESD element may be utilized with two or more lightsources to provide one or more of the functionalities discussed below ineach of the examples.

An EESD element includes storage circuitry for storing electrical energynecessary to power a light source of a photographic lighting device. Astorage circuitry includes one or more storage devices. An examplestorage device is a capacitor. In one example, a storage circuitryand/or its one or more storage devices are capable of rapidly chargingand discharging for allowing a light source to function as necessary toprovide a desired light output. An EESD may also include and/or beassociated with control circuitry for controlling the charging,discharging, and other operation of the EESD.

A light source for a photographic lighting device may be any lightsource capable of providing a desired light output for photographicimage acquisition. Example light sources include, but are not limitedto, a gas discharge tube (e.g., a halogen lamp, a xenon lamp), an LED(light emitting diode/device), an incandescent lamp, and anycombinations thereof.

In one exemplary implementation, a photographic lighting device includestwo or more light sources. A first light source is configured to fire aTTL preflash. A second light source is configured to fire a TTL mainflash. In one example, each of the first light source and the secondlight source are connected to and powered by a separate correspondingone or more EESD elements. In another example, each of the first lightsource and the second light source are connected to and powered by thesame one or more EESD elements. The first light source and the secondlight source can be of the same type or of different types. In oneexample, the second light source is a light source having a higher poweroutput capacity than the first light source. In one such example, eachlight source is connected to its own EESD element/bank with the firstlight source providing a lower power output TTL preflash and the secondlight source providing a higher power output TTL main flash.

Some single light source lighting devices have a light source that has aminimum amount of power that can be applied thereto to cause lightemission such that a light emission from such a light source mayoverpower (e.g., saturate) a sensor (e.g., a TTL metering sensor) of acamera if the light source is used for TTL preflash. Overpowering asensor (e.g., a TTL metering sensor) may prevent a camera from providingproper main flash power information such that improper exposure mayoccur. In one exemplary aspect, an example lighting device with twolight sources can include a light source that is capable of emittinglight at a low enough power to provide a TTL preflash and a light sourcethat is capable of emitting light at high enough power to provide a TTLmain flash. In such an example, a higher power light source may also becapable of typical non-TTL (or TTL) high power studio strobe flashoutput levels, while having a second light source capable of providing aTTL preflash.

In one example, where two light sources are utilized for TTL preflashand main flash emission, the first light source for TTL preflash is insubstantially similar optical path alignment with the second lightsource for TTL mainflash such that they both cast light in substantiallysimilar beam angles upon a subject. One such example would be concentricring tube light sources one within the other. In another example, thetwo light sources are selected with color temperature characteristicsthat are substantially similar such that metering of preflash is basedon the same color temperature range as the main flash exposure. In onesuch example, this may provide a balanced exposure accuracy when apreflash and main flash have substantially the same color spectrum.

A photographic lighting device may include a crossover circuitry thatwill allow a second light source configured for TTL main flash output tobe utilized for a TTL preflash at a higher power. For example, somecamera bodies are configured for a low power TTL preflash and a highpower TTL preflash. In one such example, a Nikon camera may provide afirst low power TTL preflash command to a flash device and ifinsufficient light is detected through the lens for the first preflash,a second high power TTL preflash command can be provided to a flashdevice for providing a higher power preflash for TTL (e.g., to improvesignal to noise). A crossover circuitry can be configured with hardwareand/or executable instructions for a processing element/controlcircuitry for detecting a higher power TTL command from a camera andswitching to using a higher power light source of the photographiclighting device for TTL preflash.

In some examples, a lower power TTL preflash may be needed when asubject is very close to a light source and/or when a low aperture lens(e.g., F1.4, F1.8, F2.8) is utilized at its larger open apertures.

In another exemplary implementation, a photographic lighting deviceincludes two or more EESD elements coupled to one or more light sourcesfor providing multiple symmetric light emissions within a single imageacquisition. In one example, two or more EESD elements are coupled to asingle light source. In another example, each of two or more EESDelements are coupled to a corresponding light source. Other combinationsof EESD elements and light sources (e.g., other various combinations ofmultiple to single, multiple to multiple, single to single, etc.) arecontemplated. In one example of multiple symmetric light emissions, afirst light emission is powered by one or more EESD elements of thephotographic lighting device and a second light emission is powered byone or more EESD elements of the photographic lighting device. The twolight emissions are positioned in an image acquisition window such thatthey are spaced apart by a time period approximately the same as theshutter speed/exposure time for the image acquisition. In one example,spacing apart light emissions occurs by using an energy balance point(such as a half energy point for a light emission curve) for a lightemission profile for the light source and spacing the energy balancepoint for each light emission within an image acquisition window suchthat the energy balance point of the first light emission is spaced atime period approximately the same (e.g., the same) as the exposuretime/shutter speed value for the image acquisition from the energybalance point of the second light emission. The two light emissions canbe approximately centered (e.g., centered) within the image acquisitionwindow. In another example, the two light emissions can be positionedother than centrally in the image acquisition window.

In one example, a higher efficiency of light power output may beobtained by using two or more light emissions in a single imageacquisition. In one such example, an improvement of 0.4 to 0.8 stops oflight power efficiency over a typical HSS (high speed sync) or FP-sync(focal plane sync) in which a flash emission is kept near constant frombefore first shutter blade movement until after second shutter blademovement.

Three or more flash emissions may be utilized in other examples. In onesuch example, the spacing between light emissions is a time periodequivalent to (exposure time/N−1), where N is the number of lightemissions.

Additional examples are now discussed with respect to FIGS. 2 to 18.These examples and their aspects may be applied in any combination withthe implementations discussed above. Referring now to FIG. 2, thisfigure illustrates a photographic strobe system 200 having a strobelight 204 and multiple electrical energy storage/discharge (EESD) banks,in this example two EESD banks 208, 212, that are independently operablerelative to one another. As will be described below in detail, thisindependent operability of the multiple EESD banks gives a photographergreat flexibility in controlling the amount and type of light providedby the photographic strobe system. Examples of type of light output thatsystem 200 can be configured to output include: a through-the-lens (TTL)exposure flash (or “pre-flash”); a single image-capture exposure flashpowered by one or more of the multiple EESD banks; an image-captureexposure burst powered by interleaving the discharges from the multipleEESD banks; an image-capture exposure continuous output; and anycombination of these. Specific examples of these will be described belowfollowing a more detailed description of system 200.

Strobe light 204 includes one or more light sources 216 capable ofproviding both high-intensity flash light characteristic of flashphotography and lower intensity constant or near-constant level lightoutput. By “near-constant” it is meant that light source(s) 216 may bepulsed in a manner that simulates constant level light but nonethelesshas inconsequential variations in level as an artifact of the pulsedoperation. Examples of light sources suitable for use in strobe light204 include, but are not limited to, electronic gas discharge lamps(such as xenon discharge lamps) and light-emitting diodes, and anycombination thereof, among others. When one or more xenon lamps (colortemperature of about 5500K to 6000K) are used as light source(s) 216with, for example, a conventional current-generator digitalsingle-lens-reflex (DSLR) camera, a TTL pre-flash can be a relativelylow-intensity flash on the order of 8 microseconds to 1 ms, a singleimage-capture expose flash is a relatively high-intensity flash (forexample, on the order of 1 ms), an image-capture exposure burst is arapid series of single image-capture exposure flashes over, for example,one second or more, and an image-capture exposure constant-level outputis a relatively low-to-moderate-intensity flash over a period of, forexample, between 1 ms and 5 ms in a manner the same as or similar tofocal-plane (FP) sync. FIGS. 3 to 7 illustrate exemplaryintensity-versus-time curves and corresponding exemplary exposureperiods for the flash modes just mentioned.

Referring first to FIG. 3, this figure is a graph 300 illustratesintensity-versus-time curves for a TTL pre-flash (curve 304), afull-power, first-curtain image-capture flash (curve 308) and areduced-power, first curtain image-capture flash (curve 312). Also shownis a characteristic exposure period 316 for capturing a single image toprovide a reference for the occurrences of the various flashes relativeto the exposure period. As readily seen, the TTL pre-flash (curve 304)occurs prior to the start of exposure period 316 and the full- andreduced-power first-curtain flashes (curves 308, 312, respectively)occur very shortly after the start of exposure period. FIG. 4 is a graph320 illustrating intensity-versus-time curves for two second-curtainimage-capture flashes, a full-power flash (curve 324) and areduced-power flash (curve 328), relative to an exemplary exposureperiod 332. FIG. 5 is a graph 330 illustrating an intensity-versus-timecurve 334 constant-level image-capture flash over a correspondingexposure period 338. As those skilled in the art will understand, curveincludes a series of small peaks 342 caused by very rapid pulsing of thexenon light source. Curve 334 is very similar to a like-curve for thefamiliar focal-plane (FP) sync flash. FIG. 6 is a graph 350 containing aplurality of intensity-versus-time curves 354A-F representing a seriesof like-power image-capture flashes that all occur within a single,relatively long exposure period 358. As those skilled in the art willunderstand, graph 350 is characteristic of the classic strobe situationin which motion of a subject appears to be stopped in the acquired imageat each time corresponding to the respective curve 354A-F withinexposure period 358. FIG. 7 contains a graph 360 containing curves364A-F that also represent like-power image-capture flashes. But insteadof these flashes all occurring within a single exposure period as ingraph 350, each of the flashes represented in graph 360 of FIG. 7corresponds to a separate exposure 368A-F. Thus, graph 360 representsthe rapid acquisition of a series of images using flash-lighting.

Referring again to FIG. 2, each EESD bank 208, 212 includes,respectively, storage circuitry 220, 224 for storing the electricalenergy necessary to power strobe light 204. Each storage circuitry 220,224 includes one or more storage devices (not shown), such as one ormore capacitors, capable of the rapid charging and discharging necessaryfor system to provide the desired functionality. Such storage devicesare known in the art, such that further explanation is not necessary.Each EESD bank 208, 212 also includes corresponding discharge circuitry228, 232 for controlling the discharge of electrical energy from thecorresponding storage circuitry 220, 224 to light source(s) 216, therebycontrolling the intensity and duration of the light output from strobelight 204. As those skilled in the art will readily appreciate,discharge circuitries 228, 232 includes electronic components necessaryto give system 200 the proper functionality. For example, if one or morexenon discharge lamps are used for light source(s) 216, such othercomponents (not shown) might include, for example, one or more dischargequenching components, such as a quench tube, an insulated-gate bipolartransistor or other device that assists with the operation of system 200during partial discharges, such as pre-flash discharges, reduced-powerimage-capture exposure flashes, etc. Those skilled in the art willreadily understand how to design discharge circuitries 228, 232appropriate for the type of light source(s) 216 used, such that furtherdescription of these circuitries is not necessary for those skilled inthe art to make and use photographic strobe system 200.

EESD banks 208, 212 also includes corresponding respective chargingcircuitries 236, 240 configured for charging the respective storagecircuitry 220, 224 from a suitable power source, here a pair ofhigh-voltage power supplies 244, 248 that receive their power from amains power source 258. Examples of mains power source 258 include, butare not limited to, an external battery, an internal battery, an A/Cpower supply (e.g. a connection via a power plug to an A/C powersupply), a D/C power supply (e.g. a connection via a power plug to a D/Cpower supply). In other embodiments, the power for charging circuitries236, 240 can be from a single power supply, and/or the power for the oneor more power supplies can be from a source other than a mains powersource, such as a battery. Those skilled in the art will readilyunderstand how to design charging circuitries 236, 240 and high-voltagepower supplies 244, 248 appropriate for the type storage circuitries220, 224 used, such that further description of those circuitries andpower supplies is not necessary for those skilled in the art to make anduse photographic strobe system 200.

In this example, each EESD bank 208, 212 includes a bank controller 252,256 that controls the charging and discharging functionalities of thecorresponding bank. For example, relative to discharge control each bankcontroller 252, 256 controls parameters such as rate of discharge,magnitude of discharge and length of discharge so as to produce thedesired light output from strobe light 204 for that bank. For example,when light source(s) 216 include(s) one or more xenon electronicdischarge tubes, each bank controller 252, 256 may include quenchcircuitry (not shown) for determining when to quench the discharge fromthe light sources, for example, when system 200 is providing a TTLpre-flash, a reduced-power image-capture flash (e.g., reduced by manualcontrol or based on a TTL exposure calculation), etc. As those skilledin the art will understand, such quench circuitry can include a lightintegrator (e.g., phototransistor+a capacitor) and a comparator fordetermining when strobe light 204 has output the desired amount oflight. When the quench circuitry has determined that strobe light 204has output the desired amount of light, it may send a signal to thequench circuitry of the corresponding discharge circuitry 228, 232. Eachbank controller 252, 256 may also include constant-discharge circuitry(not shown) for controlling the corresponding discharge circuitry 228,232 in a manner that strobe light 204 provides the constant-level lightoutput described above. In some embodiments, such constant-dischargecircuitry can take a form similar to conventional FP-sync circuitry.

Photographic strobe system 200 also includes a system controller 260 anda communications system 264 for communicating with a user interface (notshown) that allows a user to view and/or set operating parameters thatcontrol the operation of the strobe system and/or display information toa user such as current settings and/or status(es) of one or morecomponents of the system. In this example, communications system 264also receives a fire signal, which is typically initially triggered by acamera in response to a photographer actuating a shutter-releasecontrol. Depending on the design of photographic strobe system 200,communications system 264 can be a wired system, a wireless system or acombined wired and wireless system that handles all communications fromand to system 200. Examples of types of wireless communication thatcommunications system 264 can use include radio-frequency, infraredlight, visible light, etc.

In this example, system controller 260 controls the overall operation ofphotographic strobe system 200 and can be effectively executed as asoftware-controlled machine, such as microprocessor,application-specific integrated circuit, system on chip, etc., thatoperates under the control of suitable software 268, such as firmware,as those skilled in the art will readily appreciate. One function ofsystem controller 260 is to implement user-provided settings for causingphotographic strobe system 200 to operate according to those settings.Another function of system controller 260 is to trigger each of EESDbanks 208, 212 in response to receiving a trigger signal that isultimately initiated by a photographer, for example, via ashutter-release button on a camera. Depending on the configuration ofsystem, another function of system controller 260 is to provide variousinformation to a user, such as current settings and one or morestatuses, such as ready conditions of EESD banks 208, 212. Otherfunctions that may be performed by system controller 260, depending onthe overall functionality of system 200, include providing control datato bank controllers 252, 256 for causing EESD banks 208, 212 to drivestrobe light 204 in the desired manner, deciding which EESD bank(s) touse and/or in which order to achieve the desired light output from thestrobe light and calculating parameters necessary for causing EESD banksto drive light source(s) 216 in the appropriate manner. FIGS. 8 to 13illustrate exemplary intensity-versus-time curves and correspondingexemplary exposure periods for flash modes that photographic strobesystem 200 of FIG. 2 can be configured and/or programmed to provide.

Referring now to FIGS. 8 to 13, and also to FIGS. 2 and 3 to 7occasionally as noted, FIG. 8 is an intensity-versus-time graph 800illustrating an enhanced-intensity image-capture mode in which both EESDbanks 208, 212 (FIG. 2) fire to provide more light than either one ofthe banks could provide alone. Assuming both EESD banks 208, 212 areidentical (which they need not be), curve 804 illustrates the maximumintensity of light output by strobe light 204 powered by either of theEESD banks fired alone. Curve 808, however, illustrates the maximumintensity of light output by strobe lights 204 when EESD banks 208, 212are fired simultaneously at maximum power. Here, the maximum intensityof curve 808 is essentially twice the maximum intensity of curve 804. Inthe context of strobe light 204 being a xenon gas discharge type light,curve 808 can be realized, for example, by providing twoxenon-discharge-lamp light sources (not shown), each dedicated to acorresponding respective one of EESD banks 208, 212. Of course, either,or both, of EESD banks 208, 212 could be controlled to fire at less thanfull power, with the resulting light output being some value less thanthe power when both banks are fired simultaneously at full power.

FIG. 9 is a graph 810 illustrating a first curtain plus second curtainimage-capture mode in which system controller 260 (FIG. 2) fires one ofEESD banks 208, 212 to provide a first-curtain image-capture flash(curve 814) and fires the other EESD bank to provide a second-curtainimage-capture flash (curve 818). Plot 819 illustrates a first shutter(first curtain) movement and second shutter (second/rear curtain)movement such that flash 814 is positioned proximate the first shutterblade opening and the flash 818 is positioned proximate the secondshutter blade closing movement. As those skilled in the art will readilyappreciate, system controller 260 can be set so that the power at whichone of EESD banks 208, 212 fires is independent from the power at whichthe other fires to give the photographer maximum control over thelighting conditions

FIG. 10 is a graph 820 illustrating a first-curtain plus constant-levelimage-capture mode wherein system controller 260 (FIG. 2) fires one ofEESD banks 208, 212 to provide a first-curtain image-capture flash(curve 824) and fires the other EESD bank to provide a constant-levelflash (curve 828). Plot 829 illustrates a first shutter (first curtain)movement and second shutter (second/rear curtain) movement such thatflash 824 is positioned proximate the first shutter blade openingmovement and the constant-level light emission 828 is positionedproximate the second shutter blade closing movement. Those skilled inthe art will readily appreciate that system controller 260 can be set sothat the power of EESD banks 208, 212 are separately controllable.

FIG. 11 is a graph 830 illustrating a second-curtain plus constant-levelimage-capture mode wherein system controller 260 (FIG. 2) fires one ofEESD banks 208, 212 to provide a second-curtain image-capture flash(curve 834) and fires the other EESD bank to provide a constant-levelflash (curve 838). Plot 839 illustrates a first shutter (first curtain)movement and second shutter (second/rear curtain) movement such thatflash 834 is positioned proximate the second shutter blade openingmovement and the constant-level light emission 838 is positionedproximate the first shutter blade closing movement. Those skilled in theart will readily appreciate that system controller 260 can be set sothat the power of EESD banks 208, 212 are separately controllable.

FIG. 12 is a graph 840 that shows a single exposure period 844(corresponding to the acquisition of a single image) during whichmultiple like-power flashes are fired at a certain frequency, F, whichwill be at a maximum when the flash is fired immediately followingrecharging. In FIG. 12, the flashes are created by system controller 260(FIG. 2) alternatingly firing EESD banks 208, 212 so that each EESD bankfires at a frequency of F/2. This is represented in FIG. 13 by appendingthe curve identifiers with a “1” for EESD bank 208 and “2” for EESD bank212. Consequently, flash-intensity-versus-time curves 848A1, 848B1,848C1 are generated by firing EESD bank 208 andflash-intensity-versus-time curves 852A2, 852B2, 852C2 are generated byfiring EESD bank 212. As those skilled in the art will appreciate, thisalternating firing pattern allows for strobing strobe light 204 at amaximum frequency higher than the maximum frequency can be achieved witheither of EESD banks 208, 212 standing alone. In the present casewherein there are two EESD banks 208, 212, the enhanced firing rate canbe up to twice the firing rate of individual EESD banks. If more EESDbanks are providing, the firing rate can be increased accordingly.

FIG. 13 is a graph 860 illustrating a rapid-fire, or burst, modepossible with a photographic strobe system made in accordance with thepresent disclosure, such as system 200 of FIG. 2. Graph 860 contains aseries of flash-intensity-versus-time curves 864A1, 864B1, 864C1, 868A2,868B2, 868C2 for like-power flashes fired at a constant frequency, muchin the same manner as the flashes corresponding toflash-intensity-versus-time curves 848A1, 848B1, 848C1, 852A2, 852B2,852C2 of FIG. 12. That is, curves 864A1, 864B1, 864C1 result from systemcontroller 260 (FIG. 2) firing EESD bank 208, and curves 868A2, 868B2,868C2 result from firing EESD bank 212. However, unlike FIG. 12, theflashes corresponding to flash-intensity-versus-time curves 864A1,864B1, 864C1, 868A2, 868B2, 868C2 of FIG. 13 do not all occur within asingle exposure period, but rather corresponding to respective exposureperiods 872A-F for capturing a corresponding series of images (notshown). Like the flashes corresponding to curves 848A1, 848B1, 848C1,852A2, 852B2, 852C2 of FIG. 12, because of the interleaving the flashescorresponding to curves 864A1, 864B1, 864C1, 868A2, 868B2, 868C2 of FIG.13 can occur at a frequency higher than the maximum frequency possiblewith either of EESD banks 208, 212 used alone. As those skilled in theart will appreciate, while flash-intensity-versus-time curves 848A1,848B1, 848C1, 852A2, 852B2, 852C2 of FIG. 13 and curves 864A1, 864B1,864C1, 868A2, 868B2, 868C2 of FIG. 13 are shown as being of the samemaximum intensity, in alternative embodiments the maximum intensitiesmay vary in any manner desired, as long as system controller 260 and/orother components of photographic strobe system 200 are suitablyconfigured.

It is noted that the foregoing modes just described are merely exemplaryof operating modes that can be achieved with a multi-bank photographicstrobe system of the present disclosure. The type of mode, the number ofindividual flashes that occur within a particular mode and othercharacteristics of a particular mode can vary, not only as a function ofthe configuration of each EESD bank, but also with the number of EESDbanks provided. Those skilled in the art will surely be able to deviseuseful modes other than those shown. It is also noted that, if desired,the system controller of such a multi-bank photographic strobe systemcan be configured so that the system is able to operate in any one ormore “single” flash modes, such as the modes illustrated in FIGS. 3 to 7described above.

FIG. 14 illustrates a strobe light 1400 that can be used with, forexample, a two-bank photographic strobe system, such as system 200 ofFIG. 2. If used with system 200 of FIG. 2, strobe light 1400 of FIG. 14would be strobe light 204 of FIG. 2. Referring to FIG. 14, strobe light1400 is a gas-discharge-tube-type strobe light having a pair ofgas-discharge tubes, in this example, like-sized xenon-discharge tubes1404A-B. In the parlance of FIG. 2, above, discharge tubes 1404A-B wouldprovide strobe light 204 with two light sources 216. Strobe light 1400is configured so that discharge tube 1404A is electrically connected to,and driven by, only one EESD bank, such as EESD bank 208 of FIG. 2, andso that discharge tube 1404B is electrically connected to, and drivenby, only another EESD bank, such as EESD bank 212 of FIG. 2. Theelectrical connections between each xenon discharge tube 1404A-B includeconnections that electrically connect a positive terminal 1408A-B, anegative terminal 1412A-B and a trigger 1416A-B on each tube tocorresponding circuitry (not shown) within the respective bank to whichthat tube is electrically connected. As those skilled in the art willreadily understand, such circuitry can include one or more high-voltagestorage devices, a trigger transformer, quench circuitry and one or moreswitches. Those skilled in the art will also appreciate that alternativeembodiments can have, for example, two or more gas-discharge tubesconnected generally in parallel to the corresponding EESD banks, ifdesired.

FIGS. 15 and 16 illustrate photographic strobe device 1500 thatincorporates at least some of a photographic strobe system of thepresent disclosure, such as system 200 of FIG. 2. Strobe device 1500includes a strobe light 1504 and a body 1508 that houses onboardcircuitry and electronics (not shown) that enable system 200 of FIG. 2.Body 1508 also houses an electrical energy storage battery 161525 16 forpowering the onboard circuitry and electronics. A user interface 1604(FIG. 16) is provided on the exterior of body 1508 for allowing a userto program and/or otherwise control device 1500 as desired. In thisexample, user interface 1604 includes an electronic display 1608 (LCD,OLED, etc.) and a keypad 1612. Display 1608 display information such asmenus, settings, statuses, etc., and keypad 1612 allows a user to entersettings, request information, change menus, make selections, etc. Inthis embodiment, strobe light includes a pair of light sources 1512(only one is visible, in FIG. 15), a reflector 1516 and lens 1520. Ofcourse, many other photographic strobe devices may be made to includefeatures of the present disclosure, such that those skilled in the artwill readily understand that device 1500 of FIGS. 15 and 16 is merelyexemplary. Skilled artisans will readily understand how to make and usemany variations of devices using only the present disclosure as a guide.

FIGS. 17 and 18 illustrate several examples of how a photographic strobesystem made in accordance with the present disclosure, such as system200 of FIG. 2, can be implemented in various photographic systems.Referring first to FIG. 17, this figure illustrates a camera system 1700that includes a camera, such as a DSLR camera 1704 and a photographicstrobe device 1708. Depending on the configuration of camera 1704 and/orstrobe device 1708, camera system can also include an interface device,such as a laptop computer 1712. Laptop computer 1712 can be configuredwith appropriate hardware and software to provide a convenient userinterface to system controller 260 (FIG. 2) and/or to camera 1704, forexample, for settings various settings and operating parameters of thosedevices. Camera 1704 can be configured to communicate with each ofstrobe device 1708 and laptop either wirelessly (e.g., using one or moreIEEE 802.15 and 802.11 communications protocols) or wiredly in a mannerknown in the art.

Referring to FIG. 17, and also FIG. 2, there are a number of ways that aphotographic strobe system made in accordance with the presentdisclosure, such as system 200 of FIG. 2, can be implemented in camerasystem 1700 of FIG. 17. For example, strobe device 1708 can contain allof the components shown in photographic strobe system 200 of FIG. 2,such that communications system 264 receives directly from camera 1704information for triggering the firing of strobe light 216 in the propermode. Depending on the configuration of system controller 260 (FIG. 2),the information provided by camera 1704 can include a sync signal,camera exposure information, such as shutter speed, and/or informationnecessary for strobe device 1708 to fire in the proper mode, such aspower setting(s), mode setting(s), duration setting(s), etc. In someembodiments, some of the information needed to properly configure systemcontroller 260 of effecting a desired firing of strobe device can be setprior to firing using camera and/or the user interface for strobe device1708 available on laptop computer, if any.

FIG. 18 illustrates a photographic system 1800 similar to photographicsystem 1700 of FIG. 17 except that system 1800 of FIG. 18 includes, inaddition to camera 1804, strobe device 1808 and laptop computer 1812(optional), an intermediate device 1816 that is configured to be anintermediary device between the camera and the strobe device. In thisexample, intermediate device 1816 acts to communicate, interpret and/orsupplement information from camera 1804 for use by system controller 260(FIG. 2) aboard strobe device 1808. Intermediate device 1816 may alsoinclude a user interface (not shown) for programming strobe device 1808with the appropriate settings for providing desired operation duringuse. In one example, intermediate device 1816 is a photographic radiofor controlling one or more aspects of communication between camera 1804and strobe device 1808. In one such example, intermediate device isconnected via a hotshoe connector of camera 1804. In another suchexample, intermediate device is internal to camera 1804. Intermediatedevice 1816 may include portions that are part of camera 1804,associated with camera 1804, connected to camera 1804, part of strobedevice 1808, associated with strobe device 1808, connected to strobedevice 1808, and/or any combinations thereof.

Exemplary embodiments have been disclosed above and illustrated in theaccompanying drawings. It will be understood by those skilled in the artthat various changes, omissions and additions may be made to that whichis specifically disclosed herein without departing from the spirit andscope of the present invention.

What is claimed is:
 1. A photographic lighting device for use with acamera, the photographic lighting device including: one or more lightsources; a plurality of EESD elements coupled to the one or more lightsources; a control circuitry for causing a first light emission using afirst one of the one or more light sources and one or more of theplurality of EESD elements and a second light emission using a secondone of the one or more light sources and one or more of the plurality ofEESD elements, the control circuitry configured to cause the first andsecond light emissions to occur during a single image acquisition windowof an image acquisition by the camera, the image acquisition windowstarting when a first shutter blade of the camera starts movement andending when a second shutter blade of the camera ends movement if thecamera has shutter blades or starting when an electronic gating of asensor starts image acquisition and ending when the electronic gating ofthe sensor stops image acquisition if the camera does not have shutterblades, wherein the first light emission is timed to be positioned at afirst location in the image acquisition window and the second lightemission is timed to be positioned at a second location in the imageacquisition window such that the first and second locations are spacedapart by a time period that is about the same as a shutter speedexposure time for the image acquisition, wherein the first and secondlocations are determined in relation to an energy balance point for eachof the first and second light emissions, wherein the first light sourceand/or the second light source each include a light source selected fromthe group consisting of a gas discharge tube light source, an LED lightsource, an incandescent light source, and any combinations thereof,wherein the first light source and the second light source havesubstantially similar color temperature characteristics; and a wirelessphotographic radio for wirelessly receiving information from a remotecamera for use by the control circuitry.
 2. A photographic lightingdevice according to claim 1, wherein the control circuitry is furtherconfigured to cause one or more additional light emissions in the imageacquisition window such that the first, second, and one or moreadditional light emissions are located in the image acquisition windowwith spacing between the light emissions being a time period of shutterspeed exposure time/(N−1), where N is the number of light emissions. 3.A photographic lighting device according to claim 1, wherein the firstone of the one or more light sources and the second one of the one ormore light sources is the same light source.
 4. A photographic lightingdevice according to claim 1, wherein the first and second locations aredetermined in relation to an energy balance point for each of the firstand second light emissions, the energy balance point for each of thefirst and second light emissions occurring within the image acquisitionwindow.
 5. A photographic lighting device according to claim 1, whereinthe first and second locations are approximately centered within theimage acquisition window.
 6. A photographic lighting device according toclaim 1, wherein the first and second light emissions are symmetriclight emissions.
 7. A photographic lighting device according to claim 1,wherein the first and second light emissions are each a light emissiontype selected from the group consisting of a flash pulse, a nearconstant light emission, and a constant light emission.
 8. Aphotographic lighting device according to claim 1, wherein the firstlight source and the second light source are in substantially similaroptical path alignment.
 9. A photographic lighting device according toclaim 1, wherein the first light source and the second light source areeach concentric ring light sources aligned one within the other.
 10. Aphotographic lighting device according to claim 1, further comprising aninternal battery configured to provide power to the first EESD bank andthe second EESD bank.
 11. A photographic lighting device according toclaim 1, further comprising.
 12. A photographic lighting deviceaccording to claim 1, wherein the wireless photographic radio isinternal to the lighting device.
 13. A method of operating aphotographic lighting device in an image acquisition by a camera, thephotographic lighting device including one or more light sources and aplurality of EESD elements, the method including: causing a first lightemission using a first one of the one or more light sources and one ormore of the plurality of EESD elements, the first light emissionoccurring at a first location in an image acquisition window of theimage acquisition by the camera, the image acquisition window startingwhen a first shutter blade of the camera starts movement and ending whena second shutter blade of the camera ends movement if the camera hasshutter blades or starting when an electronic gating of a sensor startsimage acquisition and ending when the electronic gating of the sensorstops image acquisition if the camera does not have shutter blades;causing a second light emission using a second one of the one or morelight sources and one or more of the plurality of EESD elements, thesecond light emission occurring at a second location in the imageacquisition window of the same image acquisition as the first lightemission, wherein the first light emission is timed to be positioned ata first location in the image acquisition window and the second lightemission is timed to be positioned at a second location in the imageacquisition window such that the first and second locations are spacedapart by a time period that is about the same as a shutter speedexposure time for the image acquisition, wherein the first and secondlocations are determined in relation to an energy balance point for eachof the first and second light emissions, wherein the first light sourceand the second light source have substantially similar color temperaturecharacteristics; and receiving from an intermediate device aninformation for use in the causing a first light emission and thecausing a second light emission.
 14. A method according to claim 13,wherein the first and second locations are determined in relation to anenergy balance point for each of the first and second light emissions,the energy balance point for each of the first and second lightemissions occurring within the image acquisition window.
 15. A methodaccording to claim 13, wherein the first and second locations areapproximately centered within the image acquisition window.
 16. A methodaccording to claim 13, wherein the first and second light emissions aresymmetric light emissions.
 17. A method according to claim 13, whereinthe receiving includes use of a wireless photographic radio that isinternal to the photographic lighting device or external to thephotographic lighting device, and the intermediate device is internal orexternal to a camera.